// digger.cpp // Usage: Call with a list of TileClass ids separated by a space, // every (visible) tile on the map with that id will be designated for digging. // NOTE currently only works with trees // TODO add a sort of "sub-target" to dig() to make it able to designate stone as well // TODO add proper cli // TODO add interactive text based menu // TODO add ability to mark num closest to cursor #include #include #include #include #include #include #include using namespace std; #include #include #include int vec_count(vector& vec, uint16_t t) { int count = 0; for (uint32_t i = 0; i < vec.size(); ++i) { if (vec[i] == t) ++count; } return count; } //// manhattan distance //int source_distance(int sx, int sy, int sz, // int x, int y, int z, int i) //{ // // TODO changing x and y seems to be optimized away (?) // cout << x << " " << i << " " << i%16 << " " << x+(i%16) << endl; // // // handle the fact that x,y,z refers to a 16x16 grid // //x += i%16; // //y += i/16; // int dx = i%16; // int dy = i/16; // //x *= 16; // //y *= 16; // //x += dx; // //y += dy; // return abs(sx-(x+(i%16)))+abs(sy-(y+(i/16)))+abs(sz-z); //} int manhattan_distance(int x, int y, int z, int xx, int yy, int zz) { return abs(x-xx)+abs(y-yy)+abs(z-zz); } struct DigTarget { //public: DigTarget() : source_distance(0), grid_x(0), grid_y(0), local_x(0), local_y(0), real_x(0), real_y(0), z(0) { } DigTarget( int realx, int realy, int _z, int sourcex, int sourcey, int sourcez) : //grid_x(realx/16), grid_y(realy/16), //local_x(realx%16), local_y(realy%16), real_x(realx), real_y(realy), z(_z) { grid_x = realx/16; grid_y = realy/16; local_x = realx%16; local_y = realy%16; source_distance = manhattan_distance( real_x, real_y, z, sourcex, sourcey, sourcez); } DigTarget( int gridx, int gridy, int _z, int localx, int localy, int sourcex, int sourcey, int sourcez) : //source_distance(manhattan_distance( // realx, realy, realz, // sourcex, sourcey, sourcez)), grid_x(gridx), grid_y(gridy), local_x(localx), local_y(localy), z(_z) //real_x(realx), real_y(realy), real_z(realz) { real_x = (grid_x*16)+local_x; real_y = (grid_y*16)+local_y; source_distance = manhattan_distance( real_x, real_y, z, sourcex, sourcey, sourcez); } int source_distance; // the distance to the source coords, used for sorting //int source_distance() const { return _source_distance; } int grid_x, grid_y; int local_x, local_y; int real_x, real_y; int z; //int index; //const bool valid; bool operator<(const DigTarget& o) const { return source_distance < o.source_distance; } //private: // int source_x, source_y, source_z; // int _source_distance; }; int dig(DFHack::API& DF, vector& targets, int num = -1, const int x_source = 0, const int y_source = 0, const int z_source = 0) { if (num == 0) return 0; // max limit of 0, nothing to do uint32_t x_max,y_max,z_max; DFHack::t_designation designations[16][16]; uint16_t tiles[16][16]; //uint32_t count = 0; DF.getSize(x_max,y_max,z_max); // every tile found, will later be sorted by distance to source vector candidates; cout << "============================" << endl; cout << "source is " << x_source << " " << y_source << " " << z_source << endl; //int debugmaxx = 0; //int debugmaxy = 0; // walk the map for(uint32_t x = 0; x < x_max; x++) { for(uint32_t y = 0; y < y_max; y++) { for(uint32_t z = 0; z < z_max; z++) { if (z != z_source) continue; // hack to cut down on targets if(DF.isValidBlock(x,y,z)) { // read block designations and tiletype DF.ReadDesignations(x,y,z, (uint32_t *) designations); DF.ReadTileTypes(x,y,z, (uint16_t *) tiles); // search all tiles for dig targets: // visible, not yet marked for dig and matching tile type for(uint32_t lx = 0; lx < 16; lx++) { for(uint32_t ly = 0; ly < 16; ly++) { if (designations[lx][ly].bits.hidden == 0 && designations[lx][ly].bits.dig == 0 && vec_count(targets, DFHack::tileTypeTable[tiles[lx][ly]].c) > 0) { //cout << "target found at: "; //cout << x << "," << y << "," << z << "," << i << endl; //designations[i].bits.dig = DFHack::designation_default; //++count; //int realx = (x*16)+lx; //int realy = (y*16)+ly; candidates.push_back(DigTarget( x, y, z, lx, ly, x_source, y_source, z_source)); //cout << "target found at " << world_x << " " << world_y << " " << z; //cout << ", " << dt->source_distance << " tiles to source" << endl; //if (world_x > debugmaxx) // debugmaxx = world_x; //if (world_y > debugmaxy) // debugmaxy = world_y; } } // local y } // local x } } } } // TODO the following routine doesnt check if the tile is already marked for digging // if we found more tiles than was requested, sort them by distance to source, // keep the front 'num' elements and drop the rest if (num != -1 && candidates.size() > (unsigned int)num) { sort(candidates.begin(), candidates.end()); candidates.resize(num); } num = candidates.size(); cout << "============================" << endl; cout << "source is " << x_source << " " << y_source << " " << z_source << endl; // mark the tiles for actual digging for (vector::const_iterator i = candidates.begin(); i != candidates.end(); ++i) { //int grid_x = (*i).x/16; //int grid_y = (*i).y/16; //int z = (*i).z; //int local_x = (*i).x%grid_x; //int local_y = (*i).y%grid_y; cout << "designating at " << (*i).real_x << " " << (*i).real_y << " " << (*i).z; cout << ", " << (*i).source_distance << " tiles to source" << endl; // TODO this could probably be made much better, theres a big chance the trees are on the same grid // TODO move into function in DigTarget DF.ReadDesignations((*i).grid_x, (*i).grid_y, (*i).z, (uint32_t *) designations); designations[(*i).local_x][(*i).local_y].bits.dig = DFHack::designation_default; DF.WriteDesignations((*i).grid_x, (*i).grid_y, (*i).z, (uint32_t *) designations); } //cout << debugmaxx << " " << debugmaxy << endl; return num; } void test() { { DigTarget dt; //assert(!dt.valid); } { DigTarget dt( 20, 35, 16, 10, 12, 14); assert(dt.grid_x == 1); assert(dt.grid_y == 2); assert(dt.local_x == 4); assert(dt.local_y == 3); assert(dt.real_x == 20); assert(dt.real_y == 35); assert(dt.z == 16); assert(dt.source_distance == 35); //assert(dt.valid); } { DigTarget dt( 2, 4, 16, 5, 10, 10, 12, 14); assert(dt.grid_x == 2); assert(dt.grid_y == 4); assert(dt.local_x == 5); assert(dt.local_y == 10); assert(dt.real_x == 37); assert(dt.real_y == 74); assert(dt.z == 16); assert(dt.source_distance == 91); //assert(dt.valid); } //{ // sorting // DigTarget a( // 20, 35, 16, // 10, 12, 14); // DigTarget b( // 2, 4, 16, // 5, 10, // 10, 12, 14); // vector v; // v.push_back(b); // v.push_back(a); // sort(v.begin(), v.end()); // assert(*(v.begin()) == a); //} } int main (int argc, const char* argv[]) { test(); vector targets; for (int i = 1; i < argc; ++i) { targets.push_back(atoi(argv[i])); } if (targets.size() == 0) { cout << "Usage: Call with a list of TileClass ids separated by a space,\n"; cout << "every (visible) tile on the map with that id will be designated for digging.\n\n"; } else { DFHack::API DF("Memory.xml"); if(!DF.Attach()) { cerr << "DF not found" << endl; return 1; } DF.InitMap(); // TODO hack until we have a proper cli to specify origin int x_source = 134, y_source = 134, z_source = 16; // my wagon starts here; cut trees close to wagon //DF.InitViewAndCursor(); //if (!DF.getViewCoords(x_source, y_source, z_source)) //{ // cerr << "Enable cursor" << endl; // return 1; //} int count = dig(DF, targets, 10, x_source, y_source, z_source); // <-- important part cout << count << " targets designated" << endl; DF.Detach(); } #ifndef LINUX_BUILD cout << "Done. Press any key to continue" << endl; cin.ignore(); #endif return 0; }